Supporting information
Comparison of enhancement of anaerobic digestion of waste activated sludge
through adding nano-zero valent iron and zero valent iron
Yayi Wang Duanli Wang Huiying Fang
Corresponding author Tel +21 65984275 Fax +21 65984275 E-mail
wyywater126com yayiwangtongjieducn
State Key Laboratory of Pollution Control and Resources Reuse College of
Environmental Science and Engineering Tongji University Siping Road Shanghai
200092 P R China
1
Electronic Supplementary Material (ESI) for RSC AdvancesThis journal is copy The Royal Society of Chemistry 2018
Text S1
NZVI was prepared by reducing Fe(III) with sodium borohydride (NaBH4) as shown
in Eq 1 Briefly 015 molL NaBH4 was slowly added into 004 molL FeCl36H2O at
room temperature within 30 min The mixture was stirred for another 20 min
followed by standing for 1 h Ethanol (999) was used for washing and preservation
of NZVI The median diameter of the prepared NZVI was approximately 100 nm
2Fe(H2O)63+ + 6BH4
minus + 6H2O 2Fe0 (s) + 6B(OH)3 + 21H2 (g)rarr (1)
2
Text S2
Lowryrsquos method 1 was used to measure protein concentrations with bovine serum
albumin as the standard and the anthranone-sulfuric acid method 2 was used to
measure the concentration of polysaccharides The SS VSS and COD were
determined according to standard methods The concentrations of VFAs including
acetate propionate butyrate and valerate were determined using a gas
chromatograph (GC Agilent 6890N) equipped with a flame ionization detector
For CH4 and H2 concentration (PCH4 and PH2) analysis 1-mL gas samples were
collected and injected into a GC (9850T FULI) with a thermal conductivity detector
and a stainless-steel column packed with TDX-01 (1 m length) Nitrogen (99999)
was used as the carrier gas The operational temperatures of the injector detector and
column oven were 80 100 and 80 degC respectively and the bridge current was 80 mA
The cumulative volumes of CH4 and H2 (VCH4 and VH2) were calculated through the
equations VCH4 = PCH4timesVbiogas and VH2 = PH2timesVbiogas
3
Text S3
SCOD is considered the main parameter to evaluate the sludge particulate material
which enables an evaluation of the maximum level of sludge solubilization 3 VSS
reduction is an indication of sludge stability and is used for assessing the
effectiveness of a process in stabilizing sludge 4 In this study SCOD was measured
to calculate solubilization of WAS by Eq 2
119878119900119897119906119887119894119897119894119911119886119905119894119900119899 () =
119878119862119874119863119890119899 ‒ 119878119862119874119863119894119899
119879119862119874119863119894119899 ‒ 119878119862119874119863119894119899
(2)
where SCODen is the soluble COD in the WAS on day 4 of hydrolysis-acidification
and SCODin is the initial soluble COD in the WAS
VSS reduction was calculated using Eq 3
119881119878119878119903119890119889119906119888119905119894119900119899() =
119881119878119878119894119899 ‒ 119881119878119878119890119899
119881119878119878119894119899times 100
(3)
where VSSin is the initial content of VSS in the WAS and VSSen is the content of
VSS in the WAS on day 4 of the hydrolysis-acidification
4
Text S4
1 Sample collection DNA extraction and PCR amplification
WAS samples were collected from each serum bottle at the end of anaerobic digestion
(31 d) and stored at minus20 degC until use Genomic DNA was extracted triply from the
mixed liquor sludge samples using a Power Soil DNA Isolation Kit (Sangon China)
according to the manufacturerrsquos instructions The three extractions were then pooled
together and diluted to 10 ngμL for the next experimental procedure
Bacterial universal primers 338F (5ʹ-ACTCCTACGGGAGGCAGCAG-3ʹ) and 806R
(5ʹ-GGACTACHVGGGTWTCTAAT-3ʹ) were used to amplify the V3 and V4
regions of the 16S rRNA gene with the reverse primers containing 6-bp barcodes
tagging each sample (Majorbio Bio-Pharm Technology Co Ltd Shanghai China)
PCR amplifications were carried out in triplicate for each sample using 20-μL
reaction mixtures containing 5times PCR buffer 10 ng of template DNA 02 μM of each
primer 025 mM of each dNTP and 1 U FastPfu polymerase (TransGen China) The
PCRswere performed in the following conditions 95 degC for 2 min 30 cycles of 95 degC
for 30 s 55 degC for 30 s 72 degC for 30 s and a final extension at 72 degC for 5 min
Reactions were performed in a GeneAmp 9700 thermocycler (ABI USA) The
triplicate amplicons were pooled together electrophoresed on 2 (wv) agarose gels
and recovered using an AxyPrep DNA Gel Extraction Kit (Axygen USA)
2 16S rRNA gene-based Illumina library preparation sequencing and data
5
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Text S1
NZVI was prepared by reducing Fe(III) with sodium borohydride (NaBH4) as shown
in Eq 1 Briefly 015 molL NaBH4 was slowly added into 004 molL FeCl36H2O at
room temperature within 30 min The mixture was stirred for another 20 min
followed by standing for 1 h Ethanol (999) was used for washing and preservation
of NZVI The median diameter of the prepared NZVI was approximately 100 nm
2Fe(H2O)63+ + 6BH4
minus + 6H2O 2Fe0 (s) + 6B(OH)3 + 21H2 (g)rarr (1)
2
Text S2
Lowryrsquos method 1 was used to measure protein concentrations with bovine serum
albumin as the standard and the anthranone-sulfuric acid method 2 was used to
measure the concentration of polysaccharides The SS VSS and COD were
determined according to standard methods The concentrations of VFAs including
acetate propionate butyrate and valerate were determined using a gas
chromatograph (GC Agilent 6890N) equipped with a flame ionization detector
For CH4 and H2 concentration (PCH4 and PH2) analysis 1-mL gas samples were
collected and injected into a GC (9850T FULI) with a thermal conductivity detector
and a stainless-steel column packed with TDX-01 (1 m length) Nitrogen (99999)
was used as the carrier gas The operational temperatures of the injector detector and
column oven were 80 100 and 80 degC respectively and the bridge current was 80 mA
The cumulative volumes of CH4 and H2 (VCH4 and VH2) were calculated through the
equations VCH4 = PCH4timesVbiogas and VH2 = PH2timesVbiogas
3
Text S3
SCOD is considered the main parameter to evaluate the sludge particulate material
which enables an evaluation of the maximum level of sludge solubilization 3 VSS
reduction is an indication of sludge stability and is used for assessing the
effectiveness of a process in stabilizing sludge 4 In this study SCOD was measured
to calculate solubilization of WAS by Eq 2
119878119900119897119906119887119894119897119894119911119886119905119894119900119899 () =
119878119862119874119863119890119899 ‒ 119878119862119874119863119894119899
119879119862119874119863119894119899 ‒ 119878119862119874119863119894119899
(2)
where SCODen is the soluble COD in the WAS on day 4 of hydrolysis-acidification
and SCODin is the initial soluble COD in the WAS
VSS reduction was calculated using Eq 3
119881119878119878119903119890119889119906119888119905119894119900119899() =
119881119878119878119894119899 ‒ 119881119878119878119890119899
119881119878119878119894119899times 100
(3)
where VSSin is the initial content of VSS in the WAS and VSSen is the content of
VSS in the WAS on day 4 of the hydrolysis-acidification
4
Text S4
1 Sample collection DNA extraction and PCR amplification
WAS samples were collected from each serum bottle at the end of anaerobic digestion
(31 d) and stored at minus20 degC until use Genomic DNA was extracted triply from the
mixed liquor sludge samples using a Power Soil DNA Isolation Kit (Sangon China)
according to the manufacturerrsquos instructions The three extractions were then pooled
together and diluted to 10 ngμL for the next experimental procedure
Bacterial universal primers 338F (5ʹ-ACTCCTACGGGAGGCAGCAG-3ʹ) and 806R
(5ʹ-GGACTACHVGGGTWTCTAAT-3ʹ) were used to amplify the V3 and V4
regions of the 16S rRNA gene with the reverse primers containing 6-bp barcodes
tagging each sample (Majorbio Bio-Pharm Technology Co Ltd Shanghai China)
PCR amplifications were carried out in triplicate for each sample using 20-μL
reaction mixtures containing 5times PCR buffer 10 ng of template DNA 02 μM of each
primer 025 mM of each dNTP and 1 U FastPfu polymerase (TransGen China) The
PCRswere performed in the following conditions 95 degC for 2 min 30 cycles of 95 degC
for 30 s 55 degC for 30 s 72 degC for 30 s and a final extension at 72 degC for 5 min
Reactions were performed in a GeneAmp 9700 thermocycler (ABI USA) The
triplicate amplicons were pooled together electrophoresed on 2 (wv) agarose gels
and recovered using an AxyPrep DNA Gel Extraction Kit (Axygen USA)
2 16S rRNA gene-based Illumina library preparation sequencing and data
5
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Text S2
Lowryrsquos method 1 was used to measure protein concentrations with bovine serum
albumin as the standard and the anthranone-sulfuric acid method 2 was used to
measure the concentration of polysaccharides The SS VSS and COD were
determined according to standard methods The concentrations of VFAs including
acetate propionate butyrate and valerate were determined using a gas
chromatograph (GC Agilent 6890N) equipped with a flame ionization detector
For CH4 and H2 concentration (PCH4 and PH2) analysis 1-mL gas samples were
collected and injected into a GC (9850T FULI) with a thermal conductivity detector
and a stainless-steel column packed with TDX-01 (1 m length) Nitrogen (99999)
was used as the carrier gas The operational temperatures of the injector detector and
column oven were 80 100 and 80 degC respectively and the bridge current was 80 mA
The cumulative volumes of CH4 and H2 (VCH4 and VH2) were calculated through the
equations VCH4 = PCH4timesVbiogas and VH2 = PH2timesVbiogas
3
Text S3
SCOD is considered the main parameter to evaluate the sludge particulate material
which enables an evaluation of the maximum level of sludge solubilization 3 VSS
reduction is an indication of sludge stability and is used for assessing the
effectiveness of a process in stabilizing sludge 4 In this study SCOD was measured
to calculate solubilization of WAS by Eq 2
119878119900119897119906119887119894119897119894119911119886119905119894119900119899 () =
119878119862119874119863119890119899 ‒ 119878119862119874119863119894119899
119879119862119874119863119894119899 ‒ 119878119862119874119863119894119899
(2)
where SCODen is the soluble COD in the WAS on day 4 of hydrolysis-acidification
and SCODin is the initial soluble COD in the WAS
VSS reduction was calculated using Eq 3
119881119878119878119903119890119889119906119888119905119894119900119899() =
119881119878119878119894119899 ‒ 119881119878119878119890119899
119881119878119878119894119899times 100
(3)
where VSSin is the initial content of VSS in the WAS and VSSen is the content of
VSS in the WAS on day 4 of the hydrolysis-acidification
4
Text S4
1 Sample collection DNA extraction and PCR amplification
WAS samples were collected from each serum bottle at the end of anaerobic digestion
(31 d) and stored at minus20 degC until use Genomic DNA was extracted triply from the
mixed liquor sludge samples using a Power Soil DNA Isolation Kit (Sangon China)
according to the manufacturerrsquos instructions The three extractions were then pooled
together and diluted to 10 ngμL for the next experimental procedure
Bacterial universal primers 338F (5ʹ-ACTCCTACGGGAGGCAGCAG-3ʹ) and 806R
(5ʹ-GGACTACHVGGGTWTCTAAT-3ʹ) were used to amplify the V3 and V4
regions of the 16S rRNA gene with the reverse primers containing 6-bp barcodes
tagging each sample (Majorbio Bio-Pharm Technology Co Ltd Shanghai China)
PCR amplifications were carried out in triplicate for each sample using 20-μL
reaction mixtures containing 5times PCR buffer 10 ng of template DNA 02 μM of each
primer 025 mM of each dNTP and 1 U FastPfu polymerase (TransGen China) The
PCRswere performed in the following conditions 95 degC for 2 min 30 cycles of 95 degC
for 30 s 55 degC for 30 s 72 degC for 30 s and a final extension at 72 degC for 5 min
Reactions were performed in a GeneAmp 9700 thermocycler (ABI USA) The
triplicate amplicons were pooled together electrophoresed on 2 (wv) agarose gels
and recovered using an AxyPrep DNA Gel Extraction Kit (Axygen USA)
2 16S rRNA gene-based Illumina library preparation sequencing and data
5
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Text S3
SCOD is considered the main parameter to evaluate the sludge particulate material
which enables an evaluation of the maximum level of sludge solubilization 3 VSS
reduction is an indication of sludge stability and is used for assessing the
effectiveness of a process in stabilizing sludge 4 In this study SCOD was measured
to calculate solubilization of WAS by Eq 2
119878119900119897119906119887119894119897119894119911119886119905119894119900119899 () =
119878119862119874119863119890119899 ‒ 119878119862119874119863119894119899
119879119862119874119863119894119899 ‒ 119878119862119874119863119894119899
(2)
where SCODen is the soluble COD in the WAS on day 4 of hydrolysis-acidification
and SCODin is the initial soluble COD in the WAS
VSS reduction was calculated using Eq 3
119881119878119878119903119890119889119906119888119905119894119900119899() =
119881119878119878119894119899 ‒ 119881119878119878119890119899
119881119878119878119894119899times 100
(3)
where VSSin is the initial content of VSS in the WAS and VSSen is the content of
VSS in the WAS on day 4 of the hydrolysis-acidification
4
Text S4
1 Sample collection DNA extraction and PCR amplification
WAS samples were collected from each serum bottle at the end of anaerobic digestion
(31 d) and stored at minus20 degC until use Genomic DNA was extracted triply from the
mixed liquor sludge samples using a Power Soil DNA Isolation Kit (Sangon China)
according to the manufacturerrsquos instructions The three extractions were then pooled
together and diluted to 10 ngμL for the next experimental procedure
Bacterial universal primers 338F (5ʹ-ACTCCTACGGGAGGCAGCAG-3ʹ) and 806R
(5ʹ-GGACTACHVGGGTWTCTAAT-3ʹ) were used to amplify the V3 and V4
regions of the 16S rRNA gene with the reverse primers containing 6-bp barcodes
tagging each sample (Majorbio Bio-Pharm Technology Co Ltd Shanghai China)
PCR amplifications were carried out in triplicate for each sample using 20-μL
reaction mixtures containing 5times PCR buffer 10 ng of template DNA 02 μM of each
primer 025 mM of each dNTP and 1 U FastPfu polymerase (TransGen China) The
PCRswere performed in the following conditions 95 degC for 2 min 30 cycles of 95 degC
for 30 s 55 degC for 30 s 72 degC for 30 s and a final extension at 72 degC for 5 min
Reactions were performed in a GeneAmp 9700 thermocycler (ABI USA) The
triplicate amplicons were pooled together electrophoresed on 2 (wv) agarose gels
and recovered using an AxyPrep DNA Gel Extraction Kit (Axygen USA)
2 16S rRNA gene-based Illumina library preparation sequencing and data
5
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Text S4
1 Sample collection DNA extraction and PCR amplification
WAS samples were collected from each serum bottle at the end of anaerobic digestion
(31 d) and stored at minus20 degC until use Genomic DNA was extracted triply from the
mixed liquor sludge samples using a Power Soil DNA Isolation Kit (Sangon China)
according to the manufacturerrsquos instructions The three extractions were then pooled
together and diluted to 10 ngμL for the next experimental procedure
Bacterial universal primers 338F (5ʹ-ACTCCTACGGGAGGCAGCAG-3ʹ) and 806R
(5ʹ-GGACTACHVGGGTWTCTAAT-3ʹ) were used to amplify the V3 and V4
regions of the 16S rRNA gene with the reverse primers containing 6-bp barcodes
tagging each sample (Majorbio Bio-Pharm Technology Co Ltd Shanghai China)
PCR amplifications were carried out in triplicate for each sample using 20-μL
reaction mixtures containing 5times PCR buffer 10 ng of template DNA 02 μM of each
primer 025 mM of each dNTP and 1 U FastPfu polymerase (TransGen China) The
PCRswere performed in the following conditions 95 degC for 2 min 30 cycles of 95 degC
for 30 s 55 degC for 30 s 72 degC for 30 s and a final extension at 72 degC for 5 min
Reactions were performed in a GeneAmp 9700 thermocycler (ABI USA) The
triplicate amplicons were pooled together electrophoresed on 2 (wv) agarose gels
and recovered using an AxyPrep DNA Gel Extraction Kit (Axygen USA)
2 16S rRNA gene-based Illumina library preparation sequencing and data
5
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
analysis
A QuantiFluor-ST Fluorometer (Promega USA) was used to quantify the purified
amplicons and then by combining equimolar ratios of amplicons from all samples a
composite sequencing library was constructed The resulting library was sent for
paired end sequencing (2 times 250 bp) on an Illumina MiSeq platform at Majorbio Bio-
Pharm Technology Co Ltd The 16S rRNA gene sequences obtained were compared
with sequences in the GenBank database using the NCBI Blast search program
(httpblastncbinlmnihgovBlastcgi)
The sequencing data was then analyzed using Trimmomatic and FLASH software
Community estimators including richness estimator calculations (Ace and Chao
indexes) and α-diversity estimator calculations (Simpson and Shannon indexes) were
performed and analyzed using MOTHUR (version v 1301
httpwwwmothurorgwikiSchloss_SOPAlpha_diversity) The distance matrix
between aligned DNA sequences was generated from these sequences Subsequently
the Usearch program (v 71) was used with the furthest neighbor algorithm to obtain
the number of operational taxonomic units (OTUs) clone sequences with gt97
similarity were grouped together and regarded as one OTU Rarefaction curves were
generated from the observed OTUs using R (v 323) Based on the community
composition and the environmental variable (ie NZVI concentration) redundancy
analysis was performed with CANOCO 45 software
6
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Text S5
1 Bacterial variations in hydrolysis-acidification
A total of 48 phyla were detected by 16S rRNA high-throughput sequencing in the
hydrolysis-acidification testsludge samples mainly dominated by Proteobacteria
AminicenantesBacteroidetesChloroflexiFirmicutesSpirochaetes Actinobacteria and
Acidobacteria PhylaActinobacteria Firmicutes Bacteroidetes Chloroflexi and
Proteobacteriaare associated with WAS hydrolysis acidification and are usually
found in anaerobic digesters 5 For example Actinobacteria and Firmicutes can
metabolize substrates such as proteins lipids and celluloses by producing
extracellular enzymes 6 Bacteroidetes have the ability toconvert proteins and
carbohydrates to propionate and acetate in anaerobic sludge fermentation 7
The microbial populations changed significantly at the phylum level with various
additions of NZVI and ZVI (Table S3 and Fig S1a) The relative abundance of
functional bacteria affiliated with Actinobacteria Firmicutes Bacteroidetes
Chloroflexi and Proteobacteria increased with increasing NZVI addition from 00 to
100 gL the sum of the relative abundance of these phyla was 5201 of the total
bacterial amount in the control and 7385 at 100 gL NZVI This result indicates
that NZVI was beneficial for the proliferation of microorganisms related to
hydrolysis-acidification processes The impact of ZVI addition on the microbial
population was not so obvious At 100 gL ZVI the relative abundance of functional
bacteria of phyla Actinobacteria Firmicutes Bacteroidetes Chloroflexi and
7
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Proteobacteria was 5630 of the total bacterial amount while it was 5201 at 00
gL ZVI
Twenty-nine classes were detected in sludge samples from the hydrolysis-
acidification test among which 14 (483) were involved in hydrolysis-acidification
(Fig S1b) The class Betaproteobacteria which includes chemoheterotrophic
microorganisms that are responsible for the decomposition of organics 8 was the
dominant bacterial class in the experimental systems (Table S1) The relative
abundance of Betaproteobacteria increased with NZVI and ZVI addition rising to
1802 and 852 respectively at 100 gL NZVI and ZVI (Table S1) Clostridia
Gammaproteobacteria and Bacteroidia were also abundant classes the highest
proportions of which were 1347 1040 and 1070 respectively Apart from
Bacteroidia these classes increased with NZVI addition Previous studies reported
that Clostridia are the common acid-forming bacteria responsible for decomposing
solid wastes and producing organic acids 9 and Gammaproteobacteria are widely
present in anaerobic hydrolytic and acidification units for treatment of dyeing
wastewater 10
A total of 51 bacterial genera were classified among the test samples (Fig S1c) As
NZVI addition increased the relative abundance of Aminicenantes_norank
significantly decreased from 2120 (00 gL NZVI) to 043 (40 gL NZVI)
Aminicenantesare frequently detected in anaerobic digestion systems 11 In the present
8
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
study it seems that Aminicenantes_norank could not survive high NZVI addition The
relative abundance of Bacteroidetes_vadinHA17_norank genus also decreased
Bacteroidetes_vadinHA17_norank are affiliated to Bacteroidetes 12 and they
accounted for 510 of the bacterial genera in the control but only 014 after 100
gL NZVI addition This observation was consistent with the relative abundance of
Bacteroidetes decreasing at 40 and 100 gL NZVI (Fig S1a)
Candidate_division_WS6_norank was the dominant bacterial genusin the anaerobic
digestion system fed with 40 gL NZVI (1569) andits relative abundance
significantly increased after NZVI addition A recent genome-wide study predicted
Candidate phylum WS6 could be located in the anaerobic granule core and support a
fermentative lifestyle 13 We speculate that Candidate_division_WS6_norank might be
beneficial for WAS fermentation
The relative abundance of WCHB1minus60_norank and SCminusIminus84_norank genera also
increased with NZVI addition reaching 606 and 514 respectively at 40 gL
NZVI In addition the relative abundance of Gelria increased in the 40 gL NZVI-
addition system accounting for 396 of the total bacteria Gelria is affiliated to
Firmicutes and contributes to anaerobic biodegradation and methane formation 14
Our findings indicate that 40 gL NZVI stimulated the proliferation of Gelria This
was in agreement with the increase in the relative abundance of Firmicutes with NZVI
addition (Fig S1a)
9
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Taken together NZVI addition stimulated proliferation of microorganisms
responsible for hydrolysis-acidification thus enhancing the hydrolysis and
acidification processes in WAS
2 Methanogenic archaeal variations
NZVI addition significantly influenced the microbial community structure of
methanogenic archaea during the 31-day digestion process (Table S2 Table S4 and
Fig S2) As NZVI addition increased from 00 gL to 100 gL the relative abundance
of hydrogenotrophic methanogens rose from 2059 to 8399 of the total archaea
positively correlated to the NZVI dosage (Table S2) On the contrary the relative
abundance of aceticlastic methanogens first increased and then decreased with
increasing NZVI addition Specifically it was maximal at 40 gL NZVI addition and
dramatically declined on 100 gL NZVI addition Finally hydrogenotrophic
methanogens became the dominant populations at the NZVI dosage of 100 gL
(Table S2)
At the genus level Euryarchaeota_unclassified occupied the highest percentage of
the total methanogenic archaea in the control and dramatically decreased with
increasing NZVI addition (Table S4 and Figure S3b) Methanosaeta
Methanolineaand Methanobacteriumwere the dominantgenera with NZVI addition
Methanosaeta are aceticlasticmethanoarchaea 15 their relative abundance reached a
maximum at 40 gL NZVI but decreased significantly at 100 gL NZVI This
10
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
phenomenon was consistent with the finding that hydrolysis-acidification was
enhanced at 40 gL NZVI When NZVI addition increased further to 100 gL H2 was
accumulated in large amounts and hydrogenotrophic methanogens proliferated The
amount of Methanolinea a hydrogenotrophic methanogen 16 was roughly constant at
lower levels of NZVI addition but significantly increased at 100 gL NZVI which
might be caused by the accumulation of H2 in the system Methanobacterium which
grows autotrophically with H2 and CO2 as sole sources of energy and carbon 17
substantially increased with NZVI addition In the ZVI addition tests Methanolinea
and Methanosaetawere the dominant genera (Fig S2b)
The relative abundances of methanogenic archaea at the order and genus levels with
different NZVIZVI concentrations were detected(Fig S2a and b) Seven orders of
methanogenic archaea were detected among whichMethanobacteriales
Methanomicrobiales and Methanosarcinales were previously found to be the main
methanogens during anaerobic digestion in wastewater treatment
18Methanobacteriales and Methanomicrobiales are hydrogenotrophic methanogens 19
and Methanosarcinales are aceticlastic methanogens 20
It is clear that the methanogen distribution changed significantly after NZVI
addition(Fig S2a) With increasing concentration of NZVI the relative abundance of
Methanobacteriales Methanomicrobiales and Methanosarcinales increased from
3121 to 9366 (Table S2) As NZVI addition increased from 00 to 100 gL the
11
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
relative abundance of Methanobacterialesgradually increased reaching a maximum
value of 3613 at 40 gL NZVI far higher than that of 02 at 00 gL NZVI Also
the relative abundance of Methanomicrobiales increased with increasing NZVI
dosage and reached 5161 of the totalarchaeaat 100 gL NZVI The proportion of
Methanosarcinales increased then declined maximizing at 40 gL NZVI (4090)
and falling to 967 when NZVI addition was increased to 100 gL
The distribution of methanogenic archaea also changed slightly with ZVI addition
(Fig S2a) The relative abundances of Methanobacteriales Methanomicrobiales and
Methanosarcinales increased by 2952 765 and 5348 respectively as ZVI
addition increased from 00 to 100 gL It was clear that addition of NZVI and ZVI
could promote the growth of methanogenic archaea including hydrogenotrophic and
aceticlastic methanogens
References1 O H Lowry N J Rosebrough A L Farr and R J Randall J biol Chem 1951 193
265-2752 A Gaudy Ind Water Wastes 1962 7 17-273 R U Rani S A Kumar S Kaliappan I-T Yeom and J R Banu Bioresource
Technology 2012 103 415-4244 G Moussavi H Asilian and A Jamal J of Applied Sciences Research 2008 4 122-1275 X Zheng Y Su X Li N Xiao D Wang and Y Chen Environmental science amp
technology 2013 47 4262-42686 Z Yu M Morrison and F L Schanbacher Biomass to Biofuels Strategies for Global
Industries 2010 403-4137 H-Q Tan T-T Li C Zhu X-Q Zhang M Wu and X-F Zhu International Journal of
Systematic and Evolutionary Microbiology 2012 62 2613-26178 D G Cirne A Lehtomaki L Bjornsson and L L Blackall Journal of applied
microbiology 2007 103 516-5279 B Yu X Huang D Zhang Z Lou H Yuan and N Zhu RSC Adv 2016 6 24236-
24244
12
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
10 Q X Yang J Wang H T Wang X Y Chen S W Ren X L Li Y Xu H Zhang and X M Li Bioresource Technology 2012 117 155-163
11 R H Kirkegaard S J McIlroy J M Kristensen M Nierychlo S M Karst M S Dueholm M Albertsen and P H Nielsen Biorxiv 2017 104620
12 Y Zhang X Wang M Hu and P Li Applied microbiology and biotechnology 2015 99 1977-1987
13 D R Speth S Guerrero-Cruz B E Dutilh and M S Jetten Nature communications 2016 7
14 A Li Y n Chu X Wang L Ren J Yu X Liu J Yan L Zhang S Wu and S Li Biotechnology for biofuels 2013 6 3
15 K S Smith and C Ingram-Smith Trends in microbiology 2007 15 150-15516 S Sakai M Ehara I C Tseng T Yamaguchi S L Braeuer H Cadillo-Quiroz S H
Zinder and H Imachi International Journal of Systematic and Evolutionary Microbiology 2012 62 1389-1395
17 W R Kenealy and J Zeikus FEMS Microbiology Letters 1982 14 7-1018 D Boone R Castenholz and G Garrity New York [etc] Springer 200119 A S Bonin and D R Boone 2006 DOI 1010070-387-30743-5_11 231-24320 S Beckmann T Lueders M Krueger F von Netzer B Engelen and H Cypionka
Applied and Environmental Microbiology 2011 77 3749-3756
13
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Table S1 Relative abundance of functional bacteria at the class level with various NZVI and ZVI additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Betaproteobacteria 602 703 627 1421 1802 852 814
Gammaproteobacteria 441 727 596 899 1040 559 477
Alphaproteobacteria 299 508 336 769 1155 355 357
Deltaproteobacteria 592 514 654 355 566 319 461
Proteobacteria
Betaproteobacteria 602 703 627 1421 1802 852 814
Clostridia 286 443 350 1100 1347 1018 847Firmicutes
Negativicutes 0017 0004 0017 014 134 003 002
Anaerolineae 367 633 358 378 028 532 649
Chloroflexi_uncultured 256 376 239 171 030 405 304
Caldisericia 066 140 157 014 049 035 041
Chloroflexi
Chloroflexi_unclassified 103 120 092 017 003 034 054
Bacteroidia 1070 638 766 348 034 438 570
Bacteroidetes_vadinHA17 510 549 536 052 013 616 468
Bacteroidetes
Sphingobacteriia 118 085 089 230 332 066 065
Actinobacteria Actinobacteria 180 311 223 577 796 324 228
14
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Table S2 Relative abundance of methanogens at the order level with various NZVI and ZVI
additions ()
00 gL
NZVI
06 gL
NZVI
10 gL
NZVI
40 gL
NZVI
100 gL
NZVI
100 gL
ZVI
40 gL
ZVI
Methanomicrobiales 2039 1928 3001 1637 5161 2641 3726
Methanobacteriales 020 198 594 3613 3238 173 072
Hydrogenotrophic methanogens 2059 2126 3595 525 8399 2814 3798
Methanosarcinales 1062 1934 3089 4090 967 1630 2113
Methanogens 3121 406 6684 934 9366 4444 5911
Methanomassiliicoccales 003 033 099 130 011 050 085
Euryarchaeota_unclassified 6874 5906 3218 530 620 5506 4004
Others 003 033 099 130 011 050 085
Non-functional bacteria 6876 5907 3218 530 623 5506 4004
15
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
16
Table S3 The relative abundance of bacteria at the phylum level following various NZVI and ZVI additions () in hydrolysis-acidification of WASphylum 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Proteobacteria 1948 2478 2223 3457 4605 2089 2121Bacteroidetes 1735 1287 1415 6514 3885 11311 1121Chloroflexi 1043 1256 784 6118 1016 1050 1079Firmicutes 293 452 372 1135 1493 1034 8546Actinobacteria 180 311 223 5773 7966 3248 2280Percentage of functional bacteria
5201 5785 5019 6433 7385 5630 5405
Aminicenantes 2120 1817 2565 043 074 2138 2539Spirochaetae 769 682 744 217 094 396 429Candidate_division_WS6 105 087 119 1569 017 139 098WCHB1-60 067 169 117 606 869 147 096
Chlorobi 221 150 212 264 202 258 260
Atribacteria 079 123 171 030 009 487 304Synergistetes 245 142 187 027 044 247 277Saccharibacteria 077 076 066 232 349 125 118Acidobacteria 363 129 128 041 111 059 071Bacteria_unclassified 119 119 107 107 208 056 056Caldiserica 066 1408 157 014 049 035 041Cloacimonetes 150 074 087 016 002 008 034Parcubacteria 121 087 041 018 022 028 031Gemmatimonadetes 028 030 016 121 094 022 017Elusimicrobia 017 005 011 029 176 032 023Others 245 377 244 225 286 185 192Percentage of non-functional bacteria
4798 4214 4980 3566 2614 4369 4594
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
17
Table S4 The relative abundance of methanogens at the genus level following various NZVI and ZVI additions () in whole anaerobic digestionOrder Genus 00 gL
NZVI06 gL NZVI
10 gL NZVI
40 gL NZVI
100 gL NZVI
100 gL ZVI
40 gLZVI
Methanobacterium 018 191 559 3521 3043 167 066MethanobacteriasMethanobrevibacter 003 035 092 007 195 006 006
Methanomicrobiales Methanolinea 1749 1378 1770 1367 3680 2329 2617Methanospirillum 290 550 1231 271 1481 312 1109
Methanosarcinales Methanosaeta 1055 1902 3023 3754 932 1620 2072
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
18
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Fig S1 (a) Bacterial distribution at the phylum level with various NZVI and ZVI
additions (b) bacterial distribution at the class level (c) bacterial distribution at the
genus level
19
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20
Fig S2 (a) Methanogen distribution at the order level with various NZVI and ZVI
additions (b) methanogen distribution at the genus level with various NZVI and ZVI
additions
20